US9083980B2ExpiredUtilityA1
Motion vector calculation method
Est. expiryApr 19, 2022(expired)· nominal 20-yr term from priority
H04N 19/52H04N 19/573H04N 19/176H04N 19/107H04N 19/127H04N 19/513H04N 19/137H04N 19/103H04N 19/46H04N 19/16H04N 19/30H04N 19/583H04N 19/136H04N 19/70H04N 19/184H04N 19/58H04N 19/61H04N 19/105H04N 19/577H04N 19/172H04N 19/159H04N 19/423H04N 19/51H04N 19/109
99
PatentIndex Score
51
Cited by
78
References
4
Claims
Abstract
When a block (MB 22 ) of which motion vector is referred to in the direct mode contains a plurality of motion vectors, 2 motion vectors MV 23 and MV 24 , which are used for inter picture prediction of a current picture (P 23 ) to be coded, are determined by scaling a value obtained from averaging the plurality of motion vectors or selecting one of the plurality of the motion vectors.
Claims
exact text as granted — not AI-modifiedThe invention claimed is:
1. A decoding method for decoding coded data of a current block included in a current picture in direct mode, the decoding method comprising:
specifying a co-located block which is a block included in a second picture that is different from the current picture, the co-located block being located in the second picture at the same position that the current block is located in the current picture;
determining a first motion vector and a second motion vector of the current block for performing motion compensation on the current block, using a third motion vector which is a motion vector of the co-located block;
generating a first predictive image of the current block using the first motion vector of the current block and a second predictive image of the current block using the second motion vector of the current block;
generating a predictive image of the current block based on the first predictive image and the second predictive image;
decoding the coded data of the current block to obtain a difference image of the current block; and
reconstructing the current block by adding the difference image of the current block and the predictive image of the current block,
wherein, the co-located block is motion-compensated using a first motion vector corresponding to a first reference picture of the co-located block and a second motion vector corresponding to a second reference picture of the co-located block, and
wherein, in the case where the first reference picture of the co-located block is stored in a long-term picture buffer and a second reference picture of the co-located block is stored in a short-term picture buffer, (i) the third motion vector is determined to be equal to the first motion vector of the co-located block, and (ii) the first motion vector of the current block is determined to be equal to the third motion vector, and (iii) the second motion vector of the current block is determined to be a value of 0, and
wherein, in the case where the first reference picture of the co-located block is stored in a short-term picture buffer and the second reference picture of the co-located block is stored in a long-term picture buffer, (i) the third motion vector is determined to be equal to the first motion vector of the co-located block, and (ii) the first and second motion vectors of the current block are calculated by scaling the third motion vector based on a difference between display order information of the first reference picture of the current block, display order information of the second reference picture of the current block, and display order information of the current picture including the current block.
2. The decoding method according to claim 1 ,
wherein the first reference picture of the co-located block is a reference picture selected from a first reference picture list in which lower identification numbers are assigned with priority to a reference picture located prior to the current picture in display order, and the second reference picture of the co-located block is a reference picture selected from a second reference picture list in which lower identification numbers are assigned with priority to a reference picture located posterior to the current picture in display order.
3. A decoding apparatus for decoding coded data of a current block included in a current picture in direct mode, the decoding apparatus comprising:
a specifying unit operable to specify a co-located block which is a block included in a second picture that is different from the current picture, the co-located block being located in the second picture at the same position that the current block is located in the current picture;
a motion vector determining unit operable to determine a first motion vector and a second motion vector of the current block for performing motion compensation on the current block, using a third motion vector which is a motion vector of the co-located block;
a first and second predictive image generating unit operable to generate a first predictive image of the current block using the first motion vector of the current block and a second predictive image of the current block using the second motion vector of the current block;
a predictive image generating unit operable to generate a predictive image of the current block based on the first predictive image and the second predictive image;
a difference image decoding unit operable to decode the coded data of the current block to obtain a difference image of the current block; and
a block image reconstructing unit operable to reconstruct the current block by adding the difference image of the current block and the predictive image of the current block,
wherein, the co-located block is motion-compensated using a first motion vector corresponding to a first reference picture of the collocated block and a second motion vector corresponding to a second reference picture of the co-located block, and
wherein, in the case where the first reference picture of the co-located block is stored in a long-term picture buffer and a second reference picture of the co-located block is stored in a short-term picture buffer, (i) the third motion vector is determined to be equal to the first motion vector of the co-located block, and (ii) the first motion vector of the current block is determined to be equal to the third motion vector, and (iii) the second motion vector of the current block is determined to be a value of 0, and
wherein, in the case where the first reference picture of the co-located block is stored in a short-term picture buffer and the second reference picture of the co-located block is stored in a long-term picture buffer, (i) the third motion vector is determined to be equal to the first motion vector of the co-located block, and (ii) the first and second motion vectors of the current block are calculated by scaling the third motion vector based on a difference between display order information of the first reference picture of the current block, display order information of the second reference picture of the current block, and display order information of the current picture including the current block.
4. The decoding apparatus according to claim 3 ,
wherein the first reference picture of the co-located block is a reference picture selected from a first reference picture list in which lower identification numbers are assigned with priority to a reference picture located prior to the current picture in display order, and the second reference picture of the co-located block is a reference picture selected from a second reference picture list in which lower identification numbers are assigned with priority to a reference picture located posterior to the current picture in display order.Cited by (0)
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